Sculpting vesicles with active particles: Less is more

TL;DR

This study combines experiments and simulations to explore how active particles inside vesicles can induce various non-equilibrium shapes, revealing that even low particle loadings can produce significant membrane deformations.

Contribution

It provides new insights into how active particles can sculpt vesicle shapes, highlighting conditions for diverse morphologies and advancing understanding of cell membrane dynamics.

Findings

Low particle loadings induce tether-like protrusions.

High volume fractions lead to globally deformed shapes.

State diagram predicts conditions for dramatic shape changes.

Abstract

Biological cells are able to generate intricate structures and respond to external stimuli, sculpting their membrane from within. Simplified biomimetic systems can aid in understanding the principles which govern these shape changes and elucidate the response of the cell membrane under strong deformations. Here, a combined experimental and simulation approach is used to identify the conditions under which different non-equilibrium shapes and distinct active shape fluctuations can be obtained by enclosing self-propelled particles in giant vesicles. Interestingly, the most pronounced shape changes are observed at relatively low particle loadings, starting with the formation of tether-like protrusions to highly branched, dendritic structures. At high volume fractions, globally deformed vesicle shapes are observed. The obtained state diagram of vesicles sculpted by active particles predicts the conditions under which local internal forces can generate dramatic cell shape changes, such as branched structures in neurons.